Poly (polyalkylene ether urethane) polymers containing terminal epoxide groups



United 7 States Patent POLY (POLYALKYLENE ETHER URETHANE) POLYMERS CONTAINING TERMINAL EP OXIDE GROUPS 10 Claims. (01. 260-775) This invention relates to novel polyurethane polyepoxides and more particularly to polyurethane polyepoxides which are prepared from polyalkyleneether glycols and which may be cured to form highly useful elastomers.

Heretofore polyalkyleneether glycol/polyurethane polymers have been found to possess several properties which make them uniquely useful in a number of applications. It has not been possible, however, to use these polymers with advantage as liquid polymers which could be mixed with a curing agent, poured into place, and then cured to form an elastomer in situ. The difliculty usually encountered is the fact that the polymers are extremely reactive with the curing agents and, therefore, become too viscous before the mixtures can be used as practical curable liquids.

It is an object of the present invention to provide novel polyurethane polyepoxides. Another object is to provide a process for the preparation of these novel polyurethane polyepoxides from polyalkyleneether glycols. A still further object is to provide novel polyurethane pol'yepoxides which are prepared from polyalkyleneether glycols and which may be mixed with curing agents to form' relatively stable curable liquids. A still further object terminal epoxide groups. A further variation is possible 1 by reacting a molar excess of a polyalkyleneether glycol with an organic diisocyanate so as to form a polyurethane containing terminal hydroxyl groups. This may then, be reacted with two mols of an organic diisocyanate so" L as to form an isocyanate-terminated polyurethane, fol-v lowed by the reaction with two mols of a hydroxy epoxide. In addition, it is possible to preparepolyurethane polyepoxides within the scope of the present invention by reacting one mol of an organic diisocyanate with one mol of a hydroxy epoxide to form an intermediate containing terminal epoxy and isocyanate groups and then reacting two mols of this intermediate with one mol of a polyalkyleneether glycol so as to provide a polyure thane containing terminal epoxide groups. It is quite obvious that various modifications of these procedures may be used without departing from the spirit and scope is to provide a process for obtaining cured elastomers 1 from these novel polyurethane polyepoxides. jects will appear hereinafter.

These and other objects of the present invention are accomplished by a novel polyurethane polymer "having Other oba molecular weight of from about 1000 to l1,000 and being characterized by the formula wherein OG-O is a bivalent radical resulting from removal of the terminal hydrogen atoms froma'polyalkyleneether glycol having a molecular weight of from about 750 to 3500; B is a .bivalent organic radical, said" The polyurethane polyepoxides of the present, inven-' tion may be prepared by several general procedures in volving the reaction of an organic diisocyanate with 'a polyalkyleneether glycol and a compound containing one hydroxyl and one epoxide group. Thus one mol of a polyalkyleneether glycol may be reacted with two mols of an organic diisocyanate to form an isocyanate-terminated polyurethane which may then be reacted with two mols of a'hydroxy epoxide to form a polyurcthane containing of the present invention.

The polyalkyleneether glycols which are used in the I present invention may be represented by the formula HO(GO) H, wherein G is an alkylene radical and m is an integer. It is desired that m should be sufiiciently large so that the glycol has a molecular weight of from about 750 to 3500. These polyalkyleneether glycols may be prepared by the polymerization of cyclic ethers, such as alkylene oxides or dioxolanes, or from the con: densationof glycols. given glycol, the alkylene radicals represented by G need not necessarily be the same, as, for example, in polytetramethylene formal glycol. Representative glycols in elude p'olyethyleneether glycol, polypropyleneether glycol, polytetramethyleneether glycol, etc. For purposes of the present invention, polytetramethyleneether glycol is preferred. Instead of using a polyalkyleneether glycol, othr glycols such as polyalkyleneether-thioether glycols or polyalkylene-aryleneether glycols may be used Any of a wide variety of organic diisocyanates may be used to prepare the polyepoxides of the presentin- 1,4-tetramethylene diisocyanate, 1,6-hexametlrylene diisocyanate, 1,10-decamethylene diisocyanate, 1,4-cyclohexylene diisocyanate, 4,4-methylene-bis(cyclohexylisocyanate), and 1,S-tetrahydronaphthalene diisocyanate. Arylene diisocyanates, such as toluene-2,4-diisocyanate, are preferred.

prepare the polyepoxides of the present invention are compounds wherein the epoxide portion and the by droxyl portion are linked by a methylene radical. Representative compounds include glycidol and Z-methyl :glycidol. The preferred compound is glycidol.

As mentioned above, the novel polyurethane polyepoxides of the present invention may be prepared by several general procedures. In one typical method, a molar excess of an organic diisocyanate is reacted with a polyalkyleneether glycol so as to form an isocyanate-terminated polyurethane. Molar ratios of diisocyanate to glycol may range from about 12:11 to 2:1. The reaction between an organic diisocyanate-and a polyalkyleneether-glycol,

can be accomplished-by heating from 1 to 5 hoursat -C., or by heating for longer times at lower temperature,

l atented Apr. 8,,1958

It is to be understood that in any The hydroxy epoxide compounds which are used to e. g., hours at 60 C., with agitation and preferably under an inert atmosphere such as a blanket of nitrogen. The resulting isocyanate-terminated polyurethane may then be reacted with the hydroxy epoxy compound in molar ratios of polyurethane to the hydroxy epoxy compound of about 1:2. The resulting polymer will be a polyurethane containing terminal epoxide groups and having, the general formula recited above. These polyurethane polyepoxides may be described as being relatively stable, viscous liquids or solids melting below 100 C.

As described above, the polyurethane polyepoxides of the present invention may be converted to curable liquid polymers by incorporating therewith a liquid organic polyamine or polycarboxylic acid anhydride. These curable liquid polymers can be cured to produce highly useful elastomers by pouring them into molds and heating at temperatures of about 80 to 160 C. If desired, some of these liquid polymers can be cured by allowing them to stand at room temperature for longer periods of time. It is preferred that these liquid polymers be cured by the application of heat since the reaction of the polyamine or the polycarboxylic acid anhydride is relatively slow at room temperature. In view of this fact, these curable liquid polymers have sufficient pot life and stability which enables them to be used as practical curable liquid polymers. i

The organic liquid polyamines which are added to the polyurethane polyepoxides of the present invention so as to form curable liquid polymers may be any of a wide variety of aromatic or aliphatic polyamines. These polyamines must contain at least two primary or secondary amine groups, i. e., at least two amino nitrogen atoms which have hydrogen attached thereto. It is to be understood that these polyamines may contain other substituents; however, if these other substituents are functional groups, i. e., groups containing active hydrogen, they are to be less reactive with epoxides than are the amine groups. For purposes of the present invention, the preferred polyamines are the aromatic diamines such as m phenylenediamine, 2,4 diaminocumene, or mixtures thereof. Other representative diamines which may be used include aliphatic compounds such as ethylene diamine, 1,3-diaminopropanol-2, and hydroxyethylethylene diamine; aryl-alkyl compounds such as 4,4-methylenebis-(2-ehloroaniline); and polyalkylene polyamines, such as 2,2'-diamino-1,l-dimethyldiethylamine, 3,3diaminodipropylamine, and triethylene tetramine. Polymeric polyamines may also be used. Representative polymeric polyamine may be obtained by reacting one mol of the bischloroformate of polytetramethyleneether glycol with two mols of a diamine, such as m-phenylenediarnine or 4.4-metbylene-bis-(N-methylaniline). The amount of or anic polyamine which is necessary to effectively cure the polyurethane polyepoxides must be selected so as to provide at least one hydrogen-bearing amino nitrogen atom for each epoxide group. This is the theoretical amount. The amount of polyamine may be as high as about 80 to 200% of this theoretical amount, with the preferred range being from about 100 to 140%.

The Organic polyamine functions as a curing agent for the polyurethane polyepoxides. The active hydrogen on the amino nitrogen atoms reacts with the terminal epoxide groups as follows:

l n the instances where a polyamine containing more than two active hydrogen atoms attached to nitrogen atoms is used, the resulting cured polyurethane polyepoxide will be a cross-linked structure.

Another curing agent which may be incorporated with the polyurethane polyepoxides of the present invention is an organic polycarboxylic acid anhydride. Any of a wide variety of aliphatic or aromatic polycarboxylic acid anhydrides, such as glutaric anhydride, phthalic anhydride, pyromellitic dianhydride may be used. Additional compounds which may be used are succinic anhydride, maleic anhydride, phthalic anhydride substituted in the nucleus, hydrogenated phthalic anhydride, and polymerized acid anhydrides such as polyadipic and polysebacic acid anhydrides; The amount of organic polycarboxylic acid anhydride which is necessary to eflectively cure the polyurethane polyepoxides must be selected so as to provide onev mol of anhydride for each epoxide group. This is the theoretical amount. The amount of anhydride maybe as high as to 110% of this theoretical amount. The reaction mechanism involves conversion of the anhydride groups and epoxide groups to ester linkages.

The following examples will better illustrate the nature of the present invention; however, the invention is not intended to be limited to these examples. Parts are by weight unless otherwise indicated.

Example] V The polyurethane polyepoxide is'cured by mixing 15.4 1

parts of the 65% solution with 0.17 part of ethylene diamine. The liquid is poured into a mold and is heated 4 hours at 80 C., during which time the chloroform evaporates. After this treatment, the product is a thoroughly cured elastomer of light color with good resilience and fair tensile strength.

,Increasing the amount of ethylene diamine to 0.20 part or decreasing the amount of ethylene diamine to 0.134 part affects only slightly the properties of the resultant elastomer. The addition of high abrasion furnace black (3.0 parts of black for 15.4 parts of the 65% polyurethane polyepoxide solution) results in an elastomer with a much higher modulus and a lower elongation at break.

To obtain quantitative data, 62 parts .of the 65% polyurethane polyepoxide solution is mixed with 1.37 parts of 3,3'diaminodipropylamine. The liquid is put on a rubber roll mill and is mixed for 30 minutes at 8090 C. to remove solvent. Williams rings and Yerzley resilience pellets are made by curing in molds for 30 minutes at 120 C. Properties measured at 25 C. are:

Modulus at 300% elongation 350 Tensile strength at break, p. s. i 2200 Shore hardness Example 2 A mixture of 293 parts of polytetramethyleneether glycol of 977 molecular weight, containing 1% phenyl- B-naphthylamine as an antioxidant, and 34.8 parts of toluene-2,4-diisocyanate is heated with stirring for 3 hours at C. under nitrogen. After cooling to 70 C., 34.8 parts of-toluene-2,4-diisocyanate is added dropwise over /2 hour, and the mixture is heated 2 hours at 70-75" C. Then 16.3 parts of glycidol of the theoretical amount) is added. The mixture is stirred a few minutes, poured into a polyethylene bag, and heated 3 days at 80 C. in an oven. The resultant polyurethane polyepoxide is a very viscous liquid of about 3780 molecular weight. 1

100 parts of the polyurethane polyepoxide is dissolved in 200 parts of boiling chloroform and is mixed with 1.7 parts of-1,2-diaminopropanol-2; After heating 3 hours in an oven at 80 C., the product is a well-cured elastomer with good tensile strength and resilience.

Example 3 Starting with a polytetramethyleneether glycol of 1074 molecular weight, a polyurethane polyepoxide having a molecular weight of about 2820 is prepared by the method described in Example 2.

100 parts of this polyurethane polyepoxide, dissolved in 50 parts of tetrahydrofuran and. 50 parts of chloroform, is mixed with 1.57 parts of triethylene tetramine. After standing 2 days at room temperature and 3 hours at 80 C., the product is a resilient elastomer with good tensile strength. The properties of the elastomer appear unchanged after heating for 6 hours at 100 C. and then for 5 hours at 120 C. 1

The polyurethane polyepoxide can also be cured to'an elastomer using 2.5% hydroxyethylethylene diamine.

Example 4 With stirring under nitrogen, 34.8 parts of-.toluene-2,4- diisocyanate is added to 293 partsof polytetramethyleneether glycol having a-molecular weight of 977 and containing 1% phenyl-fl-naphthylamine. The liquid is heated to 100 C. and is maintained at 100 C. for 3 hours. After cooling to 70 C., 37.7 parts of diphenylmethane- 4,4- diisocyanate and 7.4 parts of glycidol are added. The mixture is stirred rapidly for 5 minutes, poured into a polyethylene bag, and heated at 80. C. for 3 days. The resulting polyurethane polyepoxide is a very viscous liquid having a molecular weight of about 7450.

100 parts of this polyurethane polyepoxide is dissolved in about 300 parts of boiling chloroform. This solution is thoroughly mixed with 1.84 parts of 3,3'-diaminodipropylamine and poured into a mold. After keeping overnight at room temperature and 4 hours at 80 C., the product is a cured elastomer with good tensile strength and high elongation at the break.

Example 5 With stirring under nitrogen, 41.8 parts of toluene-2,4- diisocyanate is added to 352- parts of polytetramethyleneether glycol having a molecular weight of 977 and containing 1% phenyl-B-maphthylamine. The liquid is heated to 100 C. and maintained at 100 C. for 3 hours. Aftercooling to 70 C., there is added'40.2 parts of diphenylmethane-4,4'-diisocyanateand 5.9. parts of glycidol. The mixture is stirred rapidly for5 minutes, poured into a polyethylene bag, andheated at 80 C. for 3 days. The polyurethane polyepoxide is an extremely viscous liquid havinga molecular weight .of about. 11,000.

100 parts of thispolyurethane polyepoxide is cured by the method of Example 4 except that 1.24 parts of 3,3- diaminodipropylamine'is used. A soft, tacky elastomer is obtained.

Exampleo A mixture of 149.3 parts of drypolytetramethyleneether glycol of 977 molecular weight containing. 1% phenylfp-naphthylamine as an antioxidant and 52.2 parts of,toluene-2,4ediisocyanate is stirred in a nitrogen atmosphere for 2 hours at 70-75 C. 26.7 parts ofQ-methyl glycidol is added dropwise over -15 minutes. The mixture is held at 70-75" C. for 2 hours. The product is. a viscous liquid having ,a molecular weight of about 1501;

with an epoxide group on each end of the chain.

30 parts of this polyurethane polyepoxicle is mixed with 1.2;parts of ethylene diamine at room temperature. I After thorough mixing, the material is allowed to age 2 days at room ,:temperature, thereby yielding a cured elastomer with good tensilestreng th and good resilience.

Example 7 (A) A mixture 135.8 parts of polytetramethyleneether glycol having a molecular weight of 970 and containing 0.2% 2,6-ditertiary butyl-4-methylphcnol as an antioxidant and 48.7 parts of toluene-2,4-diisocyanate is heated under nitrogen'at .70-'75 C. for 3 hours; Then 20.7 parts of glycidol is added and the mixture is heated at -80 C. for 22 hours. The polyurethane polyepoxide is a viscous, almost colorless liquid having a molecular weight of about 1474.

(B) A mixture of 29.4 parts of the polyurethane polyepoxide of (A) above and 1.19 parts of m-phenylenediamine is heated for 5 minutes at C. and 2 minutes at C. The liquid is poured into a mold and heated for 24 hours at 80 C. The product is a brown elastomer with moderate tensile strength and resilience, both at room temperature and at 80 C.

(C) A mixture of 29.4 parts of polyurethane polyepoxide of (A) above and 1.61 parts of a liquid diamine consisting of equal parts of rn-phenylenediamine and 2,4- diaminocumene is mixed at 100 C. and poured into a mold. After curing 24 hours at 80 C., the product is a well-cured brown elastomer with moderate tensile strength and resilience, both at room temperature and at 80 C. I

(D) A mixture of 29.4 parts of the polyurethane polyepoxide of (A) above and 3.36 parts of 4,4-methylene bis-(2-chloroaniline) is heated at 100 C. and poured into a mold. After curing 3 days at 100 C., the product is a cured but slightly tacky elastomer with moderate tensile strength and resilience.

(E) A mixture of 14.7 parts of the polyurethane polyepoxide of (A) above and 7.7 parts of a polymeric primary diamine having a molecular weight of 1278 is stirred at 80100' C., poured into a mold and cured for 24 hours at 100 C. The product is a cured elastomer with moderate tensile strength and resilience. The polymeric primary diamine used above is prepared by first mixing 1200 parts of benzene, parts of calcium hydroxide, and 32.6 parts of m-phenylene-diamine and then a solution of 171.4 parts of the bischloroformate of polytetramethyleneether glycol, havinga molecular weight of 1135, in 500 parts of benzene, is added dropwise to the stirred mixture over a 1% hour period. The mixture is stirred at room temperature overnight and then filtered. The benzene is removed at reduced pressure. The resulting polyurethanediarnine is a viscous oil.

(F) A mixture of 14.7 parts of the polyurethane polyepoxide of (A) above, 3.2 parts of the polymeric primary diamine described in (E) above, and 4.5 parts of a polymeric secondary amine having a molecular weight of 1514 is heated at 80100 C. for 10 minutes, poured into a mold, and heated for 3 days at 100 C. The product is a soft cured elastomer with low modulus, high break elongation, and good tensile strength and resilience. The polymeric secondary diamine used above is prepared by first mixing 1200 parts of benzene, 175 parts of calcium hydroxide, and 67.9 parts of 4,4 methylene bis (N- methylaniline) and then adding dropwise to the stirred mixture, over a 1% hour period, a solution of 170.3 parts of the bischloroformate of polytetramethyleneether glycol, having a molecular weight of 1135, in 500 parts of benzene. .The' mixture is stirred at room temperature overnight and then filtered. The benzene is removed at reduced pressure. The resulting polyurethane secondary diamine is a viscous oil.

(G) A mixture of 14.7 parts of the polyurethane poly- .epoxide of (A) above, 2.66 parts of pthalic anhydride,

and' 0.15 part of 4,4-methylene-bis-(N,N-dimethylaniline) is stirred at 100 C. and the liquid is poured into a mold. After curing inv an oven for 2 /2 hours at 100 C., the

product is a well-cured elastomerwithmoderate tensile strength and resilience.

Example 8 .order to disperse the carbon black in the liquid. Then t 7 2,830,038 I 7 I 8 19.6 parts of this mixture and 6.4 parts of the polymeric and 0.4 part of p-toluenesulfonic acid under a nitrogen primary diamine described in Example 7 (E) :are mixed atmosphere for 6 hours at 120-12S C. with rapid rethoroughly and poured into a pan, Aftercuringfor' 48 fluxing. After cooling and stirring for 2 hours with 1 hours at 100 C., the product is an elastomer with very part of decolorizing carbon, 4 parts .of calcium hydroxide, good tensile strength and resilience. This elastomer 5 and 1 part of an antioxidant, 4-methyl-2,6-ditertiary butylwhich contains 23 parts of carbon black per 100 parts of .phenol, the liquid portion is separated by filtration and the polymer is stronger and has ahigher modulus than a cake is washed with benzene. Volatile material is resimilar sample containing no carbon black. moved by drying in a rotating flask, finishing at 100-115 C. for 2 hours at 2 mm. pressure. -The polyformal glycol, which is solid at room temperature, has a hydroxyl Example 9 I V 10 (A) A mixture of 14.7-parts of the polyurethane polynumber of 48.5 and a'molecular weight of 2315.

epoxide of Example 7(A), 6.0 parts of a .commerical (B) 231.5 parts of the polyformal glycol prepared in A epoxy resin having the formula above and 34.8"parts of toluene-2,4-diisocyanate is heated CHOB I for 2'hours at 7075 C. Then 14.8 parts of glycidol is added, and the mixture is heated for 2 hours at 70 C. and

CHOR for l6'hours at-80 C. to form a polyurethane polyepox- 1 B ide. Curing is effected by mixing at 80 C., 22.5 parts of where 73% of the Rs are this polyurethane polyepoxide with 0.48 part of m-phenylenediamine and heating the liquid for 24 hours at 100 I C. in an oven. The product is a cured, slightly tacky I -CH=C HC elastomer with good tensile strength and resilience. and 27% of the Rs are hydrogen, and 1.80 parts of It is apparent from the foregoing examples that the ethylene diamine is stirred at room temperature and polyurethane epoxides of the present invention may be Poured into a moldt After Curing for 2 hours at C-, cured by means of polyamines or polycarboxylic acid anthe product is a thoroughly cured, tough plastic. hydrides to form highly useful elastomers. These elasto- (B) A mixture of 14.7 parts of the polyurethane polymers may be employed in the preparation of a Wide epoxide of Example 7(A), 5.3 parts of a commercial variety of articles, such as belts, hose and tubing, wire epoxy resin having the formula and cable jackets, footwear, coated fabrics, etc. When CH2 CH3 CH:GHCH 0@d3 -0CHzOH-CHr-}-OQ--Q- OCHr-CH CH:

l l I 0 CH3 OH CH3 0 where the average value for 11 0.4, and 2.16 parts of these polyurethane polyepoxides areused as curable liquid m-phenylenediamineis heated at 80-100 C. for 10 minpolymers, they may be used advantageously to form intriutes and poured into a mold. After curing for 5 hours at cate shaped articles since they may be poured into molds 80 C., the product is a thoroughly cured, tough plastic and cured in situ. The polyurethane polyepoxides may with good strength at 80 C. and at ream, temperature. also be used in combination with commercially available (C) A mixture of 75 parts ofthe polyurethane poly- 40 epoxy resins to obtain plastics which have better properepoxide of Example 7(A), 25-parts of a commercial epoxy ties than do plastics obtained from the commercial epoxy resin having the formula resins alone. Thus the combination of these polyurethane CHa polyepoxides with commercial epoxy resins produces plast I tics having a resilient nature with high thermal stability, Q P Q FQQ E 7 5 good electrical properties, and resistance to moisture.

0 I OH: O The properties of the cured elastomers which are ob and 7.5 parts of a liquid diamine, which consists of equal mined from the P y r P y p of the Present parts of m-phenylenediamine and 2,4-diaminocumene, is invention y Varied by Suitable compounding ingldi' i d at 100 C poured i molds, n cured fo 2 ents, such as carbon black, silica, calcium carbonate, and hours at 100 c. The product is a tough plastic with a '50 other fillers Generally, these compounding ingredients tensile strength of 4500 p. s. i. at 25 C. and an elongaare incorporated with the Polyurethane P y p Prior tion at break of 250%. It has excellent impact strength t0 Curingv and good t a t n th; As many widely different embodiments of this inven- (D) A mixture of 25 parts of the polyurethane .polytion y be a e Without departing from t e p t n epoxide f Example 7(A), 75 parts f a commercial epoxy scope thereof, it 1s to be understood that this invention 18 resin having the formula not limited to the specific embodiments thereof except as CH defined in the appended claims. I v What is claimed is: E7 7 1. A polyurethane polymer having a molecular weight 0 CH: 0 of from about 1000 to 11,000 and being characterized by and 14 parts of a liquid diamine, which consists of equal the formula O O 0 "G CCHrOg-NHBENHi J-O- GO- -NHB3-N'H-iL O-CHr-C CH:

A V H parts of m-phenylenediamine and 2,4-diaminocumene, is wherein O-GO is a bivalent radical resulting from restirred. at 100 'C., poured into molds and cured for 2 moval of the terminal hydrogen atoms from a polyalkylhours at 100 C. The product is ahard plastic which is eneether glycol having a molecular weight of fi'om about less brittle and has higher impact strength than a plas- 750 3500; B a bivalent Organic radical, Said radical tic prepared from 100 parts of the'commercial epoxy resin being inert t0 isocyanate groups; 71 is an integer ranging 1 from about 1 to 11; and R is selected from the group con- Em n W [e 10 sisting of hydrogen and a methyl radical.

I p v 2. The polymer of claim 1 wherein R'is hydrogen. A Polyformal glycol 18 P p y heating 416 3. The polymer of claim 2 wherein the bivalent organic parts of 1,5-penetane'diol, 127 parts of para formaldehyde, 7 radical, B, is an arylene radical. i

4. The polymer of claim 3 wherein B is a tolylene urethane polymer having a molecular weight of from about radical. 1000 to 11,000 and being characterized by the formula 5. The polymer of claim 3 wherein the bivalent radical 10 wherein OGO is a bivalent radical resulting from re- O-G O is obtained by removal f the ter inal hydrogen moval of the terminal hydrogen atoms from a polyalkylatoms from a polytetramethyleneether glycol. I

6. The polymer of claim 4 wherein the bivalent radical OG--O is obtained by removal of the terminal hydro- 750 to 3500; B is a bivalent organic radical, said radical being inertto isocyanate groups; n is an integer ranging from about 1 to 11; and R is selected from the group conatoms from a PlytetlethyleneelhFr glycol 1 sistmg of hydrogen and a methyl radlcal; and (b) an 7. A curable composition compris ng (a) a polyorganic polycarboxyfic acid anhydride urethane polymer having a molecular weight of from about 9 Th bl composifiqn f l i 7 Whgrgin h 01'.- 1000 to 11,000 and being characterized by the formula ganic polyarnine is m-phenylenediamine.

wherein O-G-O is a bivalent radical resulting from re- 10. The curable composition of claim 8 wherein the ormoval f h i l h d atoms fr a 1 1k 1 ganic polycarboxylic acid anhydride is phthalic anhydride. eneether glycol having a molecular weight of from about References Cited in the file of t patent 750 to 3500; B is a bivalent organic radical, said radical 30 being inert to isocyanate groups; n is an integer ranging UNITED STATES PATENTS from about 1 to 11; and R is selected from the group con- 2,730,531 Payne et 1956 sisting of hydrogen and a methyl radical; and (b) an FOREIGN PATENTS Y organic polyamine- 733,624 Great Britain July 13, 1955 8. A curable composition comprising (a) a poly- 35 758,433 Great Britain Oct. 3,1956

eneether glycol having a molecular weight of from about UNITED STATES PATENT OFFICE Certificate of Correction Patent No. 2,830,038 April 8, 1958 Dexter B. Pattison It is hereb certified that error appears in the printed specification of the above num ered patent requiring correction and that the said Letters Patent should read as corrected below.

Column 2, line 35, for othr read other; column 5, line 43, for -maphthylamine read --naphthylamine-; column 6, line 63, for pthalic read phthalic; column 9, claim 7, the extreme left-hand portion of the formula should appear as shown below instead of as in the patent- O QO-OHr- Signed and sealed this 20th day of May 1958.

'Attest: KARL H. AXLINE, ROBERT C. WATSON, Attestz'ng Ofioer. P Cowvmissz'oner of Patents. 

1. A POLYURETHANE POLYMER HAVING A MOLECULAR WEIGHT OF FROM ABOUT 1000 TO 11,000 AND BEING CHARACTERIZED BY THE FORMULA 